WO2014071937A1

WO2014071937A1 - Automatically dippable rear-view mirror arrangement for motor vehicles and method for producing a mirror assembly for a rear-view mirror arrangement

Info

Publication number: WO2014071937A1
Application number: PCT/DE2013/200229
Authority: WO
Inventors: Peter Krebs; Joachim Fuchs; Philip March
Original assignee: Magna Mirrors Holding Gmbh
Priority date: 2012-11-06
Filing date: 2013-10-16
Publication date: 2014-05-15
Also published as: US20150283945A1; CN104853957B; DE102012220192B3; EP2917074A1; EP2917074B1; CN104853957A; US10166926B2

Abstract

The invention relates to a rear-view mirror arrangement (1) for motor vehicles, with a housing (3) and a mirror assembly (2) arranged on the housing (3), said assembly having a front and a back for observing traffic following the vehicle of the user, wherein the degree of reflection of the mirror assembly (2) is designed to be adjustable by means of a control device. Said mirror assembly comprises two transparent support layers (5, 12), at least one reflection coating (13) and one electrically operable liquid crystal cell (6) arranged between the transparent support layers (5, 12), wherein the transparent support layer (12) facing the back of the housing (3) is an optically transparent plastic film and the rear thereof is provided with the reflection coating (13).

Description

Automatic dimming back-plane arrangement for motor vehicles and method for producing a mirror assembly for a rear-view mirror arrangement

The present invention relates to an auto-dimming rearview mirror assembly for motor vehicles and a method of manufacturing a mirror assembly for a rear-mirror assembly.

Rear-view mirror assemblies for motor vehicles have a reflective surface that allows the observation of the rearward traffic. Usually, the rear mirror assemblies are additionally designed dimmable. As a result, a dazzling is avoided by driving behind in the dark driving. In auto-dimming rear-view mirror assemblies measure or capture arranged in the mirror housing

Light sensors the brightness difference between the car forecourt and the rear traffic area. The measured values are then forwarded to an evaluation and control electronics and the reflectivity of the mirror arrangement is changed accordingly. In this case, both electrochromic rear-view mirror arrangements made of an electrochromic material and rear-mirror arrangements are known, which have a liquid-crystal layer. In both systems, the reflectivity is changeable when an electric field is applied.

The so-called electrochromic (EC) mirror assemblies have the disadvantage that this technology has a high power consumption and that the change in reflectivity is very slow. However, the known liquid crystal layer (LC) having rear-view mirror arrangements have some disadvantages. Both the known EC mirror arrangements and the previously known LC mirror arrangements consist essentially of a transparent glass pane facing the visible side, a so-called EC or LC cell lying behind it, and a lower final glass layer provided with a reflective coating. During production, the two glass layers must be aligned and arranged exactly parallel to one another. In particular, in the formation of rearview mirror assemblies with a curved surface design, the production costs are very high. The glasses are here performed correspondingly arched by bending, with two glasses have to fit exactly with each other in terms of their curvature. If the glasses arranged parallel to one another deviate from one another with respect to their curvature, the use of the rearview mirror arrangement is a given unwanted double images. The manufacture and selection of the glass sheets which are matched to one another with regard to their curvature is therefore complicated and expensive.

An LC mirror arrangement with the basic structure described above is known, for example, from DE 10 2009 020 402 A1 and DE 196 31 409 A1. Object of the present invention is therefore to develop an automatically dimming rear mirror assembly for a motor vehicle with a liquid-crystalline layer such that the rearview mirror assembly has a low weight, low power consumption and the change in reflectivity is very fast. Furthermore, the object in a further aspect of the invention is to provide a method for producing a mirror assembly, with which the mirror assembly can be produced inexpensively.

This object is achieved in a first aspect by the features specified in claim 1. In a further aspect, the object is achieved by the features specified in claim 9. By specified in claim 1 structure of the mirror assembly, wherein the housing side facing transparent support layer is formed as an optically transparent plastic film having a reflective layer, can perform a significantly reduced weight rearview mirror assembly. By using a mirror assembly with an electrically controllable liquid crystal cell, the change in the reflection behavior can be done very quickly, in addition, there is low energy consumption.

The manufacturing costs can be reduced considerably, since the film with respect to the curvature of the front-facing transparent support layer, i. can adapt the cover layer of the mirror assembly from a glass layer. Due to this ideal adaptation of the film to the glass layer, double images and optical distortions are avoided for the vehicle user.

In a further embodiment of the rearview mirror arrangement according to the invention, a frameless fixing of the mirror assembly to the housing is provided.

Further advantageous embodiments and further developments of the rearview mirror assembly according to the invention will become apparent from the dependent claims. Preferred embodiments of the rearview mirror assembly for a motor vehicle will now be described by way of example, with reference being made to the accompanying drawings by way of illustrative example.

1 shows a schematic view of a rearview mirror arrangement as an inner mirror arrangement; and

Fig. 2 shows a detail of the layer structure in a cross section of the mirror assembly.

Figure 1 shows a rearview mirror assembly 1 for installation in a motor vehicle in a schematic representation in a front view. A mirror assembly 2, with which the subsequent traffic can be observed, is held in a housing 3 in a first embodiment. For this purpose, the housing 3 has a receiving space which has a receiving opening towards the front. The housing 3 furthermore typically has a frame element 4, which fixes the mirror assembly 2 in the edge region in a clamping manner during assembly. The housing 3 is usually provided with a holding device / mirror foot on the interior, i. Can be fixed on the vehicle roof or on the windshield of a motor vehicle. In addition, at least one light sensor is installed in the housing 3 of the interior rear-view mirror with which the light intensity of the surroundings from the direction of the following traffic is detected. Furthermore, the light intensity of the apron of the motor vehicle is detected. Depending on the measured signals, activation and darkening of the mirror assembly 2 is then effected. The rearview mirror assembly 1 can of course also be designed as an exterior mirror.

The layer structure of the mirror assembly 2 is described below with reference to FIG. 2, which is equipped with an automatic dimming function. On the representation and detailed description of the light intensity detecting sensors, the control and evaluation electronics is omitted. This is known to the person skilled in the art. The representation of the layers is not to scale, but drawn only in terms of better visibility. Overall, the layer thickness of the mirror assembly 2 in the illustrated example is about 2.2 mm. Of these, the layer thickness of the transparent carrier layer 5 facing the front side V is approximately 2 mm. The layer thicknesses can also be designed differently. In particular, the carrier layer 5, which has the function of scratch protection, may have a different layer thickness, in particular a smaller layer thickness. To change the reflectance, the mirror assembly 2 according to the invention comprises a liquid crystal cell 6, which forms the core of the mirror assembly 2. This is designed to be electrically controlled. With this technology based on liquid crystals, the effect is exploited that when an electric field is applied to the liquid crystal cell, the liquid crystal molecules are oriented parallel to the electric field. In the ground state, that is to say without an electric field, the liquid-crystal molecules which are provided with color pigments are aligned in the longitudinal direction, ie the direction of passage of the light. To achieve this alignment, the alignment layers are provided.

The liquid crystal cell 6 consists essentially of the structure described below. Between two transparent electrically conductive layers 7, a liquid-crystalline layer 8 is arranged sealed. The contacting of these planar electrodes 7 is not shown. The electrically conductive layers 7 can be embodied here as an indium-tin layer (IT) or indium-tin-oxide layer (ITO). Furthermore, a layer is provided between the electrically conductive layers 7 and the liquid-crystalline layer 8, which effects an alignment of the liquid-crystal molecules in the ground state (when the electric field is not applied). These layers are referred to as alignment layer 9, which are also made transparent, and may consist of a polyimide. The liquid crystals of the liquid-crystalline layer 8 are sealed by a peripheral seal 10 arranged between the alignment layers 9. The peripheral seal 10 can be achieved via an edge-side arranged annular layer of an adhesive material. As can be seen from FIG. 2, the liquid-crystalline layer 8 comprises spherically configured spacers 11 (spacers). In further embodiments, spacer elements can also be used which have a different shape and configuration. The liquid crystal cell 6 described above is arranged between two transparent carrier layers 5, 12. Seen from the front side V of the rearview mirror arrangement, the transparent carrier layer 5 is designed as a glass layer. The glass layer has the function of a scratch protection. As a further material for the front side arranged transparent carrier layer 5, a transparent plastic can be used. On the liquid crystal cell 6 opposite side R (facing the inside of the housing side), the transparent support layer 12 is formed as a film. The material used for the film here is an optically transparent plastic film 12 preferably made of a thermoplastic Kunstsoff such as polyethylene terephthalate (PET), polycarbaonate (PC) or polymethylmethacrylate (PMMA) is used. The film is back with a non-transparent reflective Layer 13 provided. The non-transparent reflective layer 13 may in this case consist of a coating on silver, aluminum or chromium base. This layer is produced, for example, by vapor deposition or sputtering or spraying. Furthermore, a corrosion protection layer 14 is preferably finally arranged on the side facing the inner side of the housing.

In summary, the layer structure of the mirror assembly 2 is listed below starting from the front side of the rearview mirror arrangement: transparent carrier layer 5 (scratch protection)

electrically conductive layer 7 (ITO, IT)

- Alignment layer 9 (PI)

Liquid crystalline layer 8 (LC)

- Alignment layer 9 (PI)

electrically conductive layer 7 (ITO, IT)

transparent carrier layer 12 (optically transparent plastic film)

reflective layer 13

possibly corrosion protection layer 14

In a further embodiment not shown, in contrast to the previously described embodiment of the mirror assembly 2, the reflective layer is formed as a semi-transparent reflective coating. This allows the additional arrangement of a display arrangement on the back of the mirror assembly 2.

In the manufacture of the mirror assembly 2, a first assembly and a second assembly, as described in more detail below, prepared in a final manufacturing step, the edge seal 10 and the liquid crystals 8 are applied to the first or the second assembly. Under vacuum, the two assemblies are then closed bubble-free.

In the production of the first assembly, the electrically conductive layer 7 and the alignment layer 9 are produced on the front side facing transparent support plate 5 made of glass or plastic. This can also be done by vapor deposition, sputtering, spraying. The layers can be produced both successively, ie first the electrically conductive layer 7 and then the alignment layer 9, as well as in a common process step. In the production of the second assembly, a reflective coating 13 is applied to the thermoplastic transparent film 12 in known methods by vapor deposition, spraying, sputtering. On the opposite side of the film 12, the electrically conductive layer 7 and the alignment layer 9 are then produced. This can also be done by vapor deposition, sputtering, spraying. The layers can be produced both successively, ie first the electrically conductive layer 7 and then the alignment layer 9, as well as in a common process step.

Claims

Claims:

A rearview mirror assembly (1) for motor vehicles, comprising a housing (3) and a housing (3) arranged a front and a rear mirror assembly (2) for observing the subsequent traffic, wherein the reflectance of the mirror assembly (2) by a control device is made variable, comprising two transparent support layers (5, 12), at least one reflective coating (13) and an electrically controllable between the transparent support layers (5, 12) arranged liquid crystal cell (6), wherein the liquid crystal cell (6) has a liquid-crystalline layer (8 ) (LC), which is arranged sealed between two transparent electrically conductive layers (7), and wherein between the electrically conductive layers (7) and the liquid-crystalline layer (8) is provided in each case a transparent alignment layer (9), which is an alignment causes the liquid crystal molecules, characterized in that the rear side facing the housing (3) facing transparent support layer (12) adjacent to the electrically conductive layer (7) and formed as an optically transparent plastic film and this is the back with the reflection coating (13).

Second rearview mirror assembly (1) for motor vehicles according to claim 1, wherein the reflective coating (13) made of silver, aluminum or chromium material.

Third rearview mirror assembly (1) for motor vehicles according to one of the preceding claims, wherein the electrically conductive layer (7) as an indium-tin layer (IT) or indium tin oxide layer (ITO) is executed.

4. The rearview mirror assembly (1) for motor vehicles according to any one of the preceding claims, wherein the optically transparent film (12) made of a thermoplastic Kunstsoff such as polyethylene terephthalate (PET), polycarbaonate (PC) or polymethylmethacrylate (PMMA) consists.

5. rearview mirror assembly (1) for motor vehicles according to one of the preceding claims, wherein the reflection coating (13) is designed as a semi-transparent reflective coating.

6. rearview mirror assembly (1) for motor vehicles according to claim 5, wherein between the back of the mirror assembly (2) and the housing (3) a display arrangement is arranged net is.

7. rearview mirror assembly (1) for motor vehicles according to one of the preceding claims, wherein the mirror assembly (2) is provided as a final layer on the back with a corrosion protection layer (14).

8. rearview mirror assembly (1) for motor vehicles according to one of the preceding claims, wherein the front side arranged transparent support layer (5) made of glass or

Plastic exists.

9. A method for producing a mirror assembly for a rearview mirror assembly according to one of the preceding claims, wherein a first assembly is produced, and in the manufacture of the first assembly, a transparent support layer (5) made of glass or plastic is provided, this with an electrically conductive layer ( 7) and one on the electrically conductive layer (7) arranged alignment layer (9) is coated, and further a second assembly is prepared, and in the production of the second assembly, a transparent thermoplastic film as a support layer (12) is provided, this with a electrically conductive layer (7) and one on the electrically conductive layer (7) arranged alignment layer (9) is coated and arranged in a final step on the coated surface of the first or second module peripherally circumferentially a seal and within the sealed area s a liquid crystal layer (8) (LC) is applied, and the two modules are then connected under vacuum to the mirror assembly (2).